MODULE 6:Metal Oxide Semiconductor Field Effect Transistor (MOSFET)

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Module 1 Power Semiconductor Devices Version 2 EE IIT, Kharagpur 1

Transcript of MODULE 6:Metal Oxide Semiconductor Field Effect Transistor (MOSFET)

Module 1

Power Semiconductor Devices

Version 2 EE IIT, Kharagpur 1

Lesson 6

Metal Oxide Semiconductor Field

Effect Transistor (MOSFET)

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Constructional Features, operating principle and characteristics of Power Metal Oxide Semiconductor Field Effect Transistor (MOSFET). Instructional Objectives On completion the student will be able to

• Differentiate between the conduction mechanism of a MOSFET and a BJT.

• Explain the salient constructional features of a MOSFET.

• Draw the output i-v characteristics of a MOSFET and explain it in terms of the operating principle of the device.

• Explain the difference between the safe operating area of a MOSFET and a BJT.

• Draw the switching characteristics of a MOSFET and explain it.

• Design the gate drive circuit of a MOSFET.

• Interpret the manufacturer’s data sheet rating of a MOSFET.

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6.1 Introduction Historically, bipolar semiconductor devices (i.e, diode, transistor, thyristor, thyristor, GTO etc) have been the front runners in the quest for an ideal power electronic switch. Ever since the invention of the transistor, the development of solid-state switches with increased power handling capability has been of interest for expending the application of these devices. The BJT and the GTO thyristor have been developed over the past 30 years to serve the need of the power electronic industry. Their primary advantage over the thyristors have been the superior switching speed and the ability to interrupt the current without reversal of the device voltage. All bipolar devices, however, suffer from a common set of disadvantages, namely, (i) limited switching speed due to considerable redistribution of minority charge carriers associated with every switching operation; (ii) relatively large control power requirement which complicates the control circuit design. Besides, bipolar devices can not be paralleled easily.

The reliance of the power electronics industry upon bipolar devices was challenged by the introduction of a new MOS gate controlled power device technology in the 1980s. The power MOS field effect transistor (MOSFET) evolved from the MOS integrated circuit technology. The new device promised extremely low input power levels and no inherent limitation to the switching speed. Thus, it opened up the possibility of increasing the operating frequency in power electronic systems resulting in reduction in size and weight. The initial claims of infinite current gain for the power MOSFET were, however, diluted by the need to design the gate drive circuit to account for the pulse currents required to charge and discharge the high input capacitance of these devices. At high frequency of operation the required gate drive power becomes substantial. MOSFETs also have comparatively higher on state resistance per unit area of the device cross section which increases with the blocking voltage rating of the device. Consequently, the use of MOSFET has been restricted to low voltage (less than about 500 volts) applications where the ON state resistance reaches acceptable values. Inherently fast switching speed of these devices can be effectively utilized to increase the switching frequency beyond several hundred kHz. From the point of view of the operating principle a MOSFET is a voltage controlled majority carrier device. As the name suggests, movement of majority carriers in a MOSFET is controlled by the voltage applied on the control electrode (called gate) which is insulated by a thin metal oxide layer from the bulk semiconductor body. The electric field produced by the gate voltage modulate the conductivity of the semiconductor material in the region between the main current carrying terminals called the Drain (D) and the Source (S). Power MOSFETs, just like their integrated circuit counterpart, can be of two types (i) depletion type and (ii) enhancement type. Both of these can be either n- channel type or p-channel type depending on the nature of the bulk semiconductor. Fig 6.1 (a) shows the circuit symbol of these four types of MOSFETs along with their drain current vs gate-source voltage characteristics (transfer characteristics).

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G

DID

S

G

DID

S

DID

G

S

D

ID

G

S

ID

VGS n-channel depletion type

MOSFET

ID

VGS p-channel depletion type

MOSFET

ID

VGS n-channel enhancement

type MOSFET

ID

VGS p-channel enhancement

type MOSFET

(a)

(b)

Fig 6.1: Different types of power MOSFET. (a) Circuit symbols and transfer characteristics (b) Photograph of n-channel enhancement type MOSFET.

From Fig 6.1 (a) it can be concluded that depletion type MOSFETs are normally ON type switches i.e, with the gate terminal open a nonzero drain current can flow in these devices. This is not convenient in many power electronic applications. Therefore, the enhancement type MOSFETs (particularly of the n-channel variety) is more popular for power electronics applications. This is the type of MOSFET which will be discussed in this lesson. Fig 6.1 (b) shows the photograph of some commercially available n-channel enhancement type Power MOSFETs. 6.2 Constructional Features of a Power MOSFET As mentioned in the introduction section, Power MOSFET is a device that evolved from MOS integrated circuit technology. The first attempts to develop high voltage MOSFETs were by redesigning lateral MOSFET to increase their voltage blocking capacity. The resulting technology was called lateral double deffused MOS (DMOS). However it was soon realized that

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much larger breakdown voltage and current ratings could be achieved by resorting to a vertically oriented structure. Since then, vertical DMOS (VDMOS) structure has been adapted by virtually all manufacturers of Power MOSFET. A power MOSFET using VDMOS technology has vertically oriented three layer structure of alternating p type and n type semiconductors as shown in Fig 6.2 (a) which is the schematic representation of a single MOSFET cell structure. A large number of such cells are connected in parallel (as shown in Fig 6.2 (b)) to form a complete device.

FIELD OXIDE

n+ n+ n+ n+

n+

p(body) p(body)

n- (drain drift)

Drain

Gate conductor

Gate oxide

(a)

Source

Field oxide

Gate

Contact to source

Source Conductor

Gate Oxide

Conductor SingleMOSFET Cell

n+ n+ n+n+

n+

n+

n-

n-

p p

(b)

Fig. 6.2: Schematic construction of a power MOSFET (a) Construction of a single cell. (b) Arrangement of cells in a device.

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The two n+ end layers labeled “Source” and “Drain” are heavily doped to approximately the same level. The p type middle layer is termed the body (or substrate) and has moderate doping level (2 to 3 orders of magnitude lower than n+ regions on both sides). The n- drain drift region has the lowest doping density. Thickness of this region determines the breakdown voltage of the device. The gate terminal is placed over the n- and p type regions of the cell structure and is insulated from the semiconductor body be a thin layer of silicon dioxide (also called the gate oxide). The source and the drain region of all cells on a wafer are connected to the same metallic contacts to form the Source and the Drain terminals of the complete device. Similarly all gate terminals are also connected together. The source is constructed of many (thousands) small polygon shaped areas that are surrounded by the gate regions. The geometric shape of the source regions, to same extent, influences the ON state resistance of the MOSFET.

G

S

D

Parasitic BJT MOSFET

G

S

D

Body diode

Fig. 6.3: Parasitic BJT in a MOSFET cell.

n+ n+

n+ n-

D

Body spreading resistance Parasitic BJT

GS

p

One interesting feature of the MOSFET cell is that the alternating n+ n- p n+ structure embeds a parasitic BJT (with its base and emitter shorted by the source metallization) into each MOSFET cell as shown in Fig 6.3. The nonzero resistance between the base and the emitter of the parasitic npn BJT arises due to the body spreading resistance of the p type substrate. In the design of the MOSFET cells special care is taken so that this resistance is minimized and switching operation of the parasitic BJT is suppressed. With an effective short circuit between the body and the source the BJT always remain in cut off and its collector-base junction is represented as an anti parallel diode (called the body diode) in the circuit symbol of a Power MOSFET.

6.3 Operating principle of a MOSFET At first glance it would appear that there is no path for any current to flow between the

source and the drain terminals since at least one of the p n junctions (source – body and body-Drain) will be reverse biased for either polarity of the applied voltage between the source and the drain. There is no possibility of current injection from the gate terminal either since the gate oxide is a very good insulator. However, application of a positive voltage at the gate terminal with respect to the source will covert the silicon surface beneath the gate oxide into an n type layer or “channel”, thus connecting the Source to the Drain as explained next.

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The gate region of a MOSFET which is composed of the gate metallization, the gate (silicon) oxide layer and the p-body silicon forms a high quality capacitor. When a small voltage is application to this capacitor structure with gate terminal positive with respect to the source (note that body and source are shorted) a depletion region forms at the interface between the SiO2 and the silicon as shown in Fig 6.4 (a).

+ + + + + + + + + + +Gate Electrode

Depletion layerboundary.

Source Electrode Si02

Ionized acceptor

VGS1

n+

n-

p

(a)

+ + + + + + + + + + +Gate Electrode

Depletion layerboundary.

Source Electrode Si02

Ionized acceptor

VGS2

n+

n-

p

(b)

Free electron

VGS2 > VGS1

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+ + + + + + + + + + +Gate Electrode

Depletion layerboundary.

Source Electrode Si02

Ionized acceptor

VGS3

n+

n-

p

(c)

VGS3 > VGS2 > VGS1

Inversion layerwith free electrons

Fig. 6.4: Gate control of MOSFET conduction. (a) Depletion layer formation; (b) Free electron accumulation; (c) Formation of inversion layer.

The positive charge induced on the gate metallization repels the majority hole carriers from the interface region between the gate oxide and the p type body. This exposes the negatively charged acceptors and a depletion region is created.

Further increase in VGS causes the depletion layer to grow in thickness. At the same time

the electric field at the oxide-silicon interface gets larger and begins to attract free electrons as shown in Fig 6.4 (b). The immediate source of electron is electron-hole generation by thermal ionization. The holes are repelled into the semiconductor bulk ahead of the depletion region. The extra holes are neutralized by electrons from the source.

As VGS increases further the density of free electrons at the interface becomes equal to the

free hole density in the bulk of the body region beyond the depletion layer. The layer of free electrons at the interface is called the inversion layer and is shown in Fig 6.4 (c). The inversion layer has all the properties of an n type semiconductor and is a conductive path or “channel” between the drain and the source which permits flow of current between the drain and the source. Since current conduction in this device takes place through an n- type “channel” created by the electric field due to gate source voltage it is called “Enhancement type n-channel MOSFET”.

The value of VGS at which the inversion layer is considered to have formed is called the

“Gate – Source threshold voltage VGS (th)”. As VGS is increased beyond VGS(th) the inversion layer gets some what thicker and more conductive, since the density of free electrons increases further with increase in VGS. The inversion layer screens the depletion layer adjacent to it from increasing VGS. The depletion layer thickness now remains constant.

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Exercise 6.1 (after section 6.3) 1. Fill in the blank(s) with the appropriate word(s)

i. A MOSFET is a ________________ controlled ________________ carrier device.

ii. Enhancement type MOSFETs are normally ________________devices while depletion type MOSFETs are normally ________________ devices.

iii. The Gate terminal of a MOSFET is isolated from the semiconductor by a thin layer of ________________.

iv. The MOSFET cell embeds a parasitic ________________ in its structure.

v. The gate-source voltage at which the ________________ layer in a MOSFET is formed is called the ________________ voltage.

vi. The thickness of the ________________ layer remains constant as gate source voltage is increased byond the ________________ voltage.

Answer: (i) voltage, majority; (ii) off, on; (iii) SiO2, (iv) BJT, (v) inversion, threshold; (vi) depletion, threshold. 2. What are the main constructional differences between a MOSFET and a BJT? What effect do they have on the current conduction mechanism of a MOSFET?

Answer: A MOSFET like a BJT has alternating layers of p and n type semiconductors. However, unlike BJT the p type body region of a MOSFET does not have an external electrical connection. The gate terminal is insulated for the semiconductor by a thin layer of SiO2. The body itself is shorted with n+ type source by the source metallization. Thus minority carrier injection across the source-body interface is prevented. Conduction in a MOSFET occurs due to formation of a high density n type channel in the p type body region due to the electric field produced by the gate-source voltage. This n type channel connects n+ type source and drain regions. Current conduction takes place between the drain and the source through this channel due to flow of electrons only (majority carriers). Where as in a BJT, current conduction occurs due to minority carrier injection across the Base-Emitter junction. Thus a MOSFET is a voltage controlled majority carrier device while a BJT is a minority carrier bipolar device.

6.4 Steady state output i-v characteristics of a MOSFET The MOSFET, like the BJT is a three terminal device where the voltage on the gate

terminal controls the flow of current between the output terminals, Source and Drain. The source terminal is common between the input and the output of a MOSFET. The output characteristics of a MOSFET is then a plot of drain current (iD) as a function of the Drain –Source voltage (vDS) with gate source voltage (vGS) as a parameter. Fig 6.5 (a) shows such a characteristics.

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Electron Drift Velocity

ElectricField (c)

iD

VGS VGS(th)

Source region resistance

Drainresistance

n+

n-

p

(b)

n+

Drift region resistance

Channel resistance

iD

D

GS

Fig. 6.5: Output i-v characteristics of a Power MOSFET (a) i-v characteristics; (b) Components of ON-state resistance; (c) Electron drift velocity vs Electric field; (d) Transfer

Cut off (VGS < VGS (th))vgs1

VGS2

VGS3

VGS4

VGS5

VGS6 Increasing VGS

VGS – VGS (th) = VDS

Active [VGS–VGS(th)]<VDS

ohmic

rDS(ON)

iD

VDSS vDS (a)

(d)

With gate-source voltage (VGS) below the threshold voltage (vGS (th)) the MOSFET operates in the cut-off mode. No drain current flows in this mode and the applied drain–source voltage (vDS) is supported by the body-collector p-n junction. Therefore, the maximum applied voltage should be below the avalanche break down voltage of this junction (VDSS) to avoid destruction of the device.

When VGS is increased beyond vGS(th) drain current starts flowing. For small values of vDS

(vDS < (vGS – vGS(th)) iD is almost proportional to vDS. Consequently this mode of operation is called “ohmic mode” of operation. In power electronic applications a MOSFET is operated either in the cut off or in the ohmic mode. The slope of the vDS – iD characteristics in this mode is called the ON state resistance of the MOSFET (rDS (ON)). Several physical resistances as shown in Fig 6.5 (b) contribute to rDS (ON). Note that rDS (ON) reduces with increase in vGS. This is mainly due to reduction of the channel resistance at higher value of

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vGS. Hence, it is desirable in power electronic applications, to use as large a gate-source voltage as possible subject to the dielectric break down limit of the gate-oxide layer.

At still higher value of vDS (vDS > (vGS – vGS (th)) the iD – vDS characteristics deviates from

the linear relationship of the ohmic region and for a given vGS, iD tends to saturate with increase in vDS. The exact mechanism behind this is rather complex. It will suffice to state that, at higher drain current the voltage drop across the channel resistance tends to decrease the channel width at the drain drift layer end. In addition, at large value of the electric field, produced by the large Drain – Source voltage, the drift velocity of free electrons in the channel tends to saturate as shown in Fig 6.5 (c). As a result the drain current becomes independent of VDS and determined solely by the gate – source voltage vGS. This is the active mode of operation of a MOSFET. Simple, first order theory predicts that in the active region the drain current is given approximately by

2

D GS GSi = K(v - v (th)) (6.1) Where K is a constant determined by the device geometry. At the boundary between the ohmic and the active region DS GS GSv = v - v (th) (6.2)

Therefore, 2D DSi = Kv (6.3)

Equation (6.3) is shown by a dotted line in Fig 6.5 (a). The relationship of Equation (6.1)

applies reasonably well to logic level MOSFETs. However, for power MOSFETs the transfer characteristics (iD vs vGS) is more linear as shown in Fig 6.5 (d).

At this point the similarity of the output characteristics of a MOSFET with that of a BJT

should be apparent. Both of them have three distinct modes of operation, namely, (i)cut off, (ii) active and (iii) ohmic (saturation for BJT) modes. However, there are some important differences as well.

• Unlike BJT a power MOSFET does not undergo second break down.

• The primary break down voltage of a MOSFET remains same in the cut off and in

the active modes. This should be contrasted with three different break down

voltages (VSUS, VCEO & VCBO) of a BJT.

• The ON state resistance of a MOSFET in the ohmic region has positive temperature

coefficient which allows paralleling of MOSFET without any special arrangement

for current sharing. On the other hand, vCE (sat) of a BJT has negative temperature

coefficient making parallel connection of BJTs more complicated.

As in the case of a BJT the operating limits of a MOSFET are compactly represented in a

Safe Operating Area (SOA) diagram as shown in Fig 6.6. As in the case of the FBSOA of a

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BJT the SOA of a MOSFET is plotted on a log-log graph. On the top, the SOA is restricted by the absolute maximum permissible value of the drain current (IDM) which should not be exceeded even under pulsed operating condition. To the left, operating restriction arise due to the non zero value of rDS(ON) corresponding to vGS = vGS(Max). To the right, the first operating restriction is due to the limit on the maximum permissible junction temperature rise which depends on the power dissipation inside the MOSFET. This limit is different for DC (continuous) and pulsed operation of different pulse widths. As in the case of a BJT the pulsed safe operating areas are useful for shaping the switching trajectory of a MOSFET. A MOSFET does not undergo “second break down” and no corresponding operating limit appears on the SOA. The final operation limit to the extreme right of the SOA arises due to the maximum permissible drain source voltage (VDSS) which is decided by the avalanche break down voltage of the drain -body p-n junction. This is an instantaneous limit. There is no distinction between the forward biased and the reverse biased SOAs for the MOSFET. They are identical.

Log (iD)

IDM

Max.Power Dissipation Limit (Timax)

10-5sec

10-4sec

10-3sec

Primary voltage breakdownlimit

Fig. 6.6: Safe operating area of a MOSFET.

DC

rDS(ON) limit(VGS = VGS(max))

Log (vDS)VDSS

Due to the presence of the anti parallel “body diode”, a MOSFET can not block any reverse voltage. The body diode, however, can carry an RMS current equal to IDM. It also has a substantial surge current carrying capacity. When reverse biased it can block a voltage equal to VDSS.

For safe operation of a MOSFET, the maximum limit on the gate source voltage (VGS

(Max)) must be observed. Exceeding this voltage limit will cause dielectric break down of the thin gate oxide layer and permanent failure of the device. It should be noted that even static charge inadvertently put on the gate oxide by careless handling may destroy it. The device user should ground himself before handling any MOSFET to avoid any static charge related problem.

Exercise 6.2 Fill in the blank(s) with the appropriate word(s)

i. A MOSFET operates in the ________________ mode when vGS < vGS(th)

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ii. In the ohmic region of operation of a MOSFET vGS – vGS (th) is greater than

________________.

iii. rDS (ON) of a MOSFET ________________ with increasing vGS.

iv. In the active region of operation the drain current iD is a function of ________________

alone and is independent of ________________.

v. The primary break down voltage of MOSFET is ________________ of the drain

current.

vi. Unlike BJT a MOSFET does not undergo ________________.

vii. ________________ temperature coefficient of rDS(ON) of MOSFETs facilitates easy

________________ of the devices.

viii. In a Power MOSFET the relation ship between iD and vGS – vGS(th) is almost

________________ in the active mode of operation.

ix. The safe operating area of a MOSFET is restricted on the left hand side by the

________________ limit.

Answer: (i) Cut off; (ii) vDS; (iii) decreases; (iv) vGS, vDS; (v) independent; (vi) second break down; (vii) Positive, paralleling; (viii) linear; (ix) rDS (ON);

6.5 Switching characteristics of a MOSFET 6.5.1 Circuit models of a MOSFET cell

Like any other power semiconductor device a MOSFET is used as a switch in all power electronic converters. As a switch a MOSFET operates either in the cut off mode (switch off) or in the ohmic mode (switch on). While making transition between these two states it traverses through the active region. Being a majority carrier device the switching process in a MOSFET does not involve any inherent delay due to redistribution of minority charge carriers. However, formation of the conducting channel in a MOSFET and its disappearance require charging and discharging of the gate-source capacitance which contributes to the switching times. There are several other capacitors in a MOSFET structure which are also involved in the switching process. Unlike bipolar devices, however, these switching times can be controlled completely by the gate drive circuit design.

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CGD

CGD1

CGD2

idealized

Actual

VGS – VGS (th) = VDS VDS

(b)

G

D

S

CGD

CGS

(cut off) G

D

S

CGD

CGS

iD = f(vGS) (Active)

G

D

S

CGD

CGS

rDS(ON) (Ohmic)

(c)

Fig. 6.7: Circuit model of a MOSFET (a) MOSFET capacitances (b) Variation of CGD with VDS (c) Circuit models.

Drain bodydepletion layer

n+

n-

p

(a)

n+

CGD

D

GS

Fig 6.7 (a) shows three important capacitances inherent in a MOSFET structure. The most prominent capacitor in a MOSFET structure is formed by the gate oxide layer between the gate metallization and the n+ type source region. It has the largest value (a few nano farads) and remains more or less constant for all values of vGS and vDS. The next largest capacitor (a few hundred pico forwards) is formed by the drain – body depletion region directly below the gate metallization in the n- drain drift region. Being a depletion layer capacitance its value is a strong function of the drain source voltage vDS. For low values of vDS (vDS < (vGS – vGS (th))) the value of CGD (CGD2) is considerably higher than its value for large vDS as shown in Fig 6.7 (b). Although variation of CGD between CGD1 and CGD2 is continuous a step change in the value of CGD at vDS = vGS – vGS(th) is assumed for simplicity. The lowest value capacitance is formed between the drain and the source terminals due to the drain – body depletion layer away form the gate metallization and below the source metallization. Although this capacitance is important for some design considerations (such as snubber design, zero voltage switching etc) it does not appreciably affect the “hard switching” performance of a MOSFET. Consequently, it will be neglected in our discussion. From the

Gate oxide

CDS

CGS

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above discussion and the steady state characteristics of a MOSFET the circuit models of a MOSFET in three modes of operation can be drawn as shown in Fig 6.7 (c).

6.5.2 Switching waveforms

The switching behavior of a MOSFET will be described in relation to the clamped inductive circuit shown in Fig 6.8. For simplicity the load current is assumed to remain constant over the small switching interval. Also the diode DF is assumed to be ideal with no reverse recovery current. The gate is assumed to be driven by an ideal voltage source giving a step voltage between zero and Vgg in series with an external gate resistance Rg.

VD

DF

if

IO

Vgg

Rg

CGD

CGS

ig

iD

VDS

+

-

Fig. 6.8: Clamped inductive switching circuit using a MOSFET.

+-

To turn the MOSFET on, the gate drive voltage changes from zero to Vgg. The gate

source voltage which was initially zero starts rising towards Vgg with a time constant τ1 = Rg (CGS + CGD1) as shown in Fig 6.9.

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∫ ∫

∫ ∫

∫ ∫

∫ ∫

∫ ∫Vgg

t

t

t

t

ig

iD, if

τ2 = Rg(CGS+CGD2)

iD

τ2

tON

I0ros (ON)

∫ ∫

VGS VGSI0

VGS(th)

igI0

VDS

gg

g

VR

τ1 = Rg(CGS+CGD1)

τ1

gg

g

VR

−igI0

I0 I0 if

if

iD

toff

td(off) trvi trv2 tfi tdON tri tfv1 tfv2

Fig. 6.9: Switching waveforms of a clamped inductive switching circuit using MOSFET

Note that during this period the drain voltage vDS is clamped to the supply voltage VD through the free wheeling diode DF. Therefore, CGS and CGD can be assumed to be connected in parallel effectively. A part of the total gate current ig charges CGS while the other part discharges CGD.

Till vGS reaches vGS (th) no drain current flows. This time period is called turn on delay

time (td(ON)). Note that td(ON) can be controlled by controlling Rg. Byond td(ON) iD increases linearly with vGS and in a further time tri (current rise time) reaches Io. The corresponding value of vGS and ig are marked as VGS Io and ig Io respectively in Fig 6.9.

At this point the complete load current has been transferred to the MOSFET from the free

wheeling diode DF. iD does not increase byond this point. Since in the active region iD and vGS are linearly related, vGS also becomes clamped at the value vGSIo. The gate current ig now discharges CGD and the drain voltage starts falling.

( ) ( )g GG GS oDS GS GD GD

GD GD g

i V - V Id d dv = v + v = v = = 6.4dt dt dt C C R

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The fall of vDS occurs in two distinct intervals. When the MOSFET is in the active region (vDS > (vGS – vGS (th)) CGD = CGD1.Since CGD1 << CGD2, vDS falls rapidly. This fast fall time of vDS is marked tfv1 in Fig 6.9. However, once in the ohmic region, CGD = CGD2 >> CGD1. Therefore, rate of fall of vDS slows down considerably (tfv2). Once vDS reaches its on state value (rDS(ON) Io) vGS becomes unclamped and increases towards Vgg with a time constant τ2 = Rg (CGS + CGD2). Note that all switching periods can be reduced by increasing Vgg or / and decreasing Rg. The total turn on time is tON = td(ON) + tri + tfv1 + tfv2.

To turn the MOSFET OFF, Vgg is reduced to zero triggering the exact reverse process of

turn on to take place. The corresponding waveforms and switching intervals are show in Fig 6.9. The total turn off time toff = td(off) + trv1 + trv2 + tfi.

6.5.3 MOSFET Gate Drive MOSFET, being a voltage controlled device, does not require a continuous gate current to keep it in the ON state. However, it is required to charge and discharge the gate-source and the gate-drain capacitors in each switching operation. The switching times of a MOSFET essentially depends on the charging and discharging rate of these capacitors. Therefore, if fast charging and discharging of a MOSFET is desired at fast switching frequency the gate drive power requirement may become significant. Fig 6.10 (a) shows a typical gate drive circuit of a MOSFET.

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Logic level gate pulse

VGG VD

RG

R1

Q1

Q2

Q3

(a)

VGG

1G

1

RR +

(β +1)

VGG

GR

(b)

VD

DF IL

G S

D

B RB

(c)

D

RG G

R

R

S

(d)

Fig. 6.10: MOSFET gate drive circuit. (a) Gate drive circuit; (b) Equivalent circuit during turn on and off;(b) Effect of parasitic BJT; (d) Parallel connection of MOSFET’s.

To turn the MOSFET on the logic level input to the inverting buffer is set to high state so that transistor Q3 turns off and Q1 turns on. The top circuit of Fig 6.10 (b) shows the equivalent circuit during turn on. Note that, during turn on Q1 remains in the active region. The effective gate resistance is RG + R1 / (β1 + 1). Where, β1 is the dc current gain of Q1.

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To turn off the MOSFET the logic level input is set to low state. Q3 and Q2 turns on whole Q1 turns off. The corresponding equivalent circuit is given by the bottom circuit of Fig 6.10 (b)

The switching time of the MOSFET can be adjusted by choosing a proper value of RG.

Reducing RG will incase the switching speed of the MOSFET. However, caution should be exercised while increasing the switching speed of the MOSFET in order not to turn on the parasitic BJT in the MOSFET structure inadvertently. The drain-source capacitance (CDS) is actually connected to the base of the parasitic BJT at the p type body region. The body source short has some nonzero resistance. A very fast rising drain-source voltage will send sufficient displacement current through CDS and RB as shown in Fig 6.10 (c). The voltage drop across RB may become sufficient to turn on the parasitic BJT. This problem is largely avoided in a modern MOSFET design by increasing the effectiveness of the body-source short. The devices are now capable of dvDS/dt in excess to 10,000 V/μs. Of course, this problem can also be avoided by slowing down the MOSFET switching speed.

Since MOSFET on state resistance has positive temperature coefficient they can be

paralleled without taking any special precaution for equal current sharing. To parallel two MOSFETs the drain and source terminals are connected together as shown in Fig 6.10 (d). However, small resistances (R) are connected to individual gates before joining them together. This is because the gate inputs are highly capacitive with almost no losses. Some stray inductance of wiring may however be present. This stray inductance and the MOSFET capacitance can give rise to unwanted high frequency oscillation of the gate voltage that can result in puncture of the gate qxide layer due to voltage increase during oscillations. This is avoided by the damping resistance R.

Exercise 6.3 1. Fill in the blank(s) with the appropriate word(s)

i. The Gate-Source capacitance of a MOSFET is the ________________ among all three

capacitances.

ii. The Gate-Drain transfer capacitance of a MOSFET has large value in the

________________ region and small value in the ________________ region.

iii. During the turn on delay time the MOSFET gate source voltage rises from zero to the

________________ voltage.

iv. The voltage fall time of a MOSFET is ________________ proportional to the gate

charging resistance.

v. Unlike BJT the switching delay times in a MOSFET can be controlled by proper design

of the ________________ circuit.

Answer: (i) largest; (ii) ohmic, active; (iii) threshold; (iv) inversely; (v) gate drive.

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2. A Power MOSFET has the following data CGS = 800 pF ; CGD = 150 pF; gf = 4; vGS(th) = 3V; It is used to switch a clamped inductive load (Fig 6.8) of 20 Amps with a supply voltage VD=

200V. The gate drive voltage is vgg = 15V, and gate resistance Rg = 50Ω. Find out maximum

value of ddidt

and DSdvdt

during turn ON.

Answer: During turn on ( )D f gs gsi g v - v (th)≈

gsDf

dvdi = gdt dt

But ( ) gs gg gsGS GD

g

dv V - vC + C =

dt R

( ) ( )gsD f

f gg GS GD

dvdi g= g = V - vdt dt R C + C g gs∴

( ) ( ) ( )( )

f gg gsD fgg gs Min

Max g GS GD g GS GD

g V - v (th)di g= V - v =dt R C + C R C + C

Dgs gs D

disince for v < v (th) i = = 0dt

( ) 9D-12

Max

di 4= 15-3 = 1.01×10 A secdt 50×950×10

From equation (6.4)

gg GS oDS

GD g

V - V , Idv =dt C R

For Io = 20 A, vgs(th) = 3V, and gf = 4

oGS o gs

f

I 20V , I = + v (th) = + 3 = 8 voltsg 4

6DS-12

dv 15-8= = 933×10 V sec.dt 150×10 ×50

6.6 MOSFET Ratings Steady state operating limits of a MOSFET are usually specified compactly as a safe

operating area (SOA) diagram. The following limits are specified. VDSS: This is the drain-source break down voltage. Exceeding this limit will destroy the

device due to avalanche break down of the body-drain p-n junction.

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IDM: This is the maximum current that should not be exceeded even under pulsed current operating condition in order to avoid permanent damage to the bonding wires.

Continuous and Pulsed power dissipation limits: They indicate the maximum

allowable value of the VDS, iD product for the pulse durations shown against each limit. Exceeding these limits will cause the junction temperature to rise beyond the acceptable limit.

All safe operating area limits are specified at a given case temperature. In addition, several important parameters regarding the dynamic performance of the

device are also specified. These are Gate threshold voltage (VGS (th)): The MOSFET remains in the cut off region when vGS

in below this voltage. VGS (th) decreases with junction temperature. Drain Source on state resistance (rDS (ON)): This is the slope of the iD – vDS

characteristics in the ohmic region. Its value decreases with increasing vGS and increases with junction temperature. rDS (ON) determines the ON state power loss in the device.

Forward Transconductance (gfs): It is the ratio of iD and (vGS – vGS(th)). In a MOSFET

switching circuit it determines the clamping voltage level of the gate – source voltage and thus influences dvDS/dt during turn on and turn off.

Gate-Source breakdown voltage: Exceeding this limit will destroy the gate structure of

the MOSFET due to dielectric break down of the gate oxide layer. It should be noted that this limit may by exceeded even by static charge deposition. Therefore, special precaution should be taken while handing MOSFETs.

Input, output and reverse transfer capacitances (CGS, CDS & CGD): Value of these capacitances are specified at a given drain-source and gate-source voltage. They are useful for designing the gate drive circuit of a MOSFET.

In addition to the main MOSFET, specifications pertaining to the “body diode” are also

provided. Specifications given are Reverse break down voltage: This is same as VDSS

Continuous ON state current (IS): This is the RMS value of the continuous current that can flow through the diode.

Pulsed ON state current (ISM): This is the maximum allowable RMS value of the ON

state current through the diode given as a function of the pulse duration. Forward voltage drop (vF): Given as an instantaneous function of the diode forward

current. Reverse recovery time (trr) and Reverse recovery current (Irr): These are specified as

functions of the diode forward current just before reverse recovery and its decreasing slope (diF/dt).

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Exercise 6.4 Fill in the blank(s) with the appropriate word(s)

i. The maximum voltage a MOSFET can with stand is ________________ of drain current.

ii. The FBSOA and RBSOA of a MOSFET are ________________.

iii. The gate source threshold voltage of a MOSFET ________________ with junction

temperature while the on state resistance ________________ with junction temperature.

iv. The gate oxide of a MOSFET can be damaged by ________________ electricity.

v. The reverse break down voltage of the body diode of a MOSFET is equal to

________________ while its RMS forward current rating is equal to ________________.

Answer: (i) independent; (ii) identical; (iii) decreases, increases; (iv) static; (v) VDSS; IDM.

Reference [1] “Evolution of MOS-Bipolar power semiconductor Technology”, B. Jayant Baliga,

Proceedings of the IEEE, VOL.76, No-4, April 1988. [2] “Power Electronics ,Converters Application and Design” Third Edition, Mohan,

Undeland, Robbins. John Wiley & Sons Publishers 2003. [3] GE – Power MOSFET data sheet.

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Lesson Summary • MOSFET is a voltage controlled majority carrier device.

• A Power MOSFET has a vertical structure of alternating p and n layers.

• The main current carrying terminals of an n channel enhancement mode MOSFET are called the Drain and the Source and are made up of n+ type semiconductor.

• The control terminal is called the Gate and is isolated form the bulk semiconductor by a thin layer of SiO2.

• p type semiconductor body separates n+ type source and drain regions.

• A conducting n type channel is produced in the p type body region when a positive voltage greater than a threshold voltage is applied at the gate.

• Current conduction in a MOSFET occurs by flow of electron from the source to the drain through this channel.

• When the gate source voltage is below threshold level a MOSFET remains in the “Cut Off” region and does not conduct any current.

• With vGS > vGS (th) and vDS < (vGS – vGS (th)) the drain current in a MOSFET is proportional to vDS. This is the “Ohmic region” of the MOSFET output characteristics.

• For larger values of vDS the drain current is a function of vGS alone and does not depend on vDs. This is called the “active region” of the MOSFET.

• In power electronic applications a MOSFET is operated in the “Cut Off” and Ohmic regions only.

• The on state resistance of a MOSFET (VDS (ON)) has a positive temperature coefficient. Therefore, MOSFETs can be easily paralleled.

• A MOSFET does not undergo second break down.

• The safe operating area (SOA) of a MOSFET is similar to that of a BJT except that it does not have a second break down limit.

• Unlike BJT the maximum forward voltage withstanding capability of a MOSFET does not depend on the drain current.

• The safe operating area of a MOSFET does not change under Forward and Reverse bias conditions.

• The drain – body junction in a MOSFET structure constitute an anti parallel diode connected between the source and the drain. This is called the MOSFET “body – diode.”

• The body diode of a MOSFET has the same break down voltage and forward current rating as the main MOSFET.

• The switching delays in a MOSFET are due to finite charging and discharging time of the input and output capacitors.

• Switching times of a MOSFET can be controlled completely by external gate drive design.

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• The input capacitor along with the gate drive resistance determine the current rise and fall time of a MOSFET during switching.

• The transfer capacitor (Cgd) determines the drain voltage rise and fall times.

• rDS (ON) of a MOSFET determines the conduction loss during ON period.

• rDS (ON) reduces with higher vgs. Therefore, to minimize conduction power loss maximum permissible vgs should be used subject to dielectric break down of the gate oxide layer.

• The gate oxide layer can be damaged by static charge. Therefore MOSFETs should be handled only after discharging one self through proper grounding.

• For similar voltage rating, a MOSFET has a relatively higher conduction loss and lower switching loss compared to a BJT. Therefore, MOSFETs are more popular for high frequency (>50 kHz) low voltage (<100 V) circuits.

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Practice Problems and Answers

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Practice Problems

1. How do you expect the gate source capacitance of a MOSFET to varry with gate source voltage. Explain your answer.

2. The gate oxide layer of a MOSFET is 1000 Angstrom thick Assuming a break down field

strength of 5 × 106 V/cm and a safely factor of 50%, find out the maximum allowable gate source voltage.

3. Explain why in a high voltage MOSFET switching circuit the voltage rise and fall time is

always greater than current fall and rise times. 4. A MOSFET has the following parameters

VGS(th) = 3V, gfs = 3, CGS = 800 PF, CGD = 250 PF. The MOSFET is used to switch an inductive load of 15 Amps from 150V supply. The switching frequency is 50 kHz. The gate drive circuit has a driving voltage of 15V and output resistance of 50Ω. Find out the switching loss in the MOSFET.

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Answer to practice problems

1. When the gate voltage is zero the thickness of the gate-source capacitance is approximately equal to the thickness of the gate oxide layer. As the gate source voltage increases the width of the depletion layer in the p body region also increases. Since the depletion layer is a region of immobile charges it in effect increases the thickness of the gate-source capacitance and hence the value of this capacitances decreases with increasing vGS. However, as vGS is increased further free electrons generated by thermal ionization get attracted towards the gate oxide-semiconductor interface. These free electrons screen the depletion layer partially and the gate-source capacitance starts increasing again. When vGS is above vgs (th) the inversion layer completely screens the depletion layer and the effective thickness of the gate-source capacitance becomes once again equal to the thickness of the oxide layer. There after the value of CGS remains more or less constant.

2. From the given data the break down gate source voltage GS BD BD gsv = E × t where EBD = Break down field strength tgs = thickness of the oxide layer. So 6 -8

GS BDv = 5×10 ×1000×10 = 50V

Let gs Maxv be the maximum allowable gate source voltage assuming 50% factor of safety.

gs Max GS BD

gs Max

1.5 v = v = 50 V

50 v = V 33 Volts.1.5

∴ ≈

3. We Know that for MOSFET

( )( )

D fs GS GS

gg GSDfs GS fs

g GS

i = g V - V (th)

V - vdi d = g v = gdt dt R C

During current rise Vgg >> vGS

fsDgg

g GS

ori fi g GS o

fs gg

gdi Vdt R C

It = t R C where I = load current.g V

∴ ≈

∴ ≈

Now From equation (6.4)

gg g s o ggDS

g GD g GD

V - V , I Vd v =dt R C R C

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Since Vgg >> Vgs, Io

Drr fv g GD D

gg

Vt = t R C where V = Load voltage.V

∴ ≈

o G Sri fi

rr fr D fs G D

I Ct t = = t t V g C

That is current rise and fall times are much shorter than voltage rise and fall times.

4. Referring to Fig 6.9 energy loss during switching occurs during intervals tri , tfv1, tfv2, trv2,trv1, and tfi. For simplicity it will be assumed that tfv2 = trv2 = 0. Also the rise and fall of iD and vDS will be assumed to be linear. During tri D fs gs gsi = g (v - v (th))

gg gsDfs gs fs

GS GD g

V - vdi d= g v = gdt dt (C + C )R

fs ggDgg gs

GS GD g

g Vdi sinceV >> v during current risedt (C + C )R

∴ ≈

ori GS GD g

fs gg

I t = (C + C )Rg V

Energy loss during tri is

2

D oON1 ri D GS GD g

fs gg

V I1E = t V Io = (C + C )R2 2g V

During tfv

gg gs, oDS

GD g

V - V IdV =dt C R

ogs o gs

fs

IBut V , I = + v (th)g

ogg gs

DS fs

g GD

IV - v (th) -dV g=dt R C

Dfv g GD

ogg gs

fs

Vt = R CIV - V (th) - g

Energy loss during tfv is ON2 fv o D

1E = t I V2

2

D og GD

ogg gs

fs

V I= RI2 V - v (th) - g

⎛ ⎞⎜ ⎟⎝ ⎠

C

∴ Energy loss during Turn on is

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( )

( )D o g o GS GD D GD

ON ON1 ON2fs gg gg gs

V I R I C + C V CE = E + E = +2 g V V - V (th)

⎡ ⎤⎢ ⎥⎢ ⎥⎣ ⎦

From the symmetry of the Turn ON and the Turn OFF operation of MOSFET (i.e. tri = tfi, tfv = trv) ON OFFE = E ∴ Total switching energy lass is Esw = EON + EOFF = 2 EON

ggo fs GSsw D o g GD

gs o fsgg GD

gg gg

VD VI g C E = V I R C 1+ + V (th) I gV C -V V

⎡ ⎤⎢ ⎥⎛ ⎞⎢ ⎥∴ ⎜ ⎟⎢ ⎥⎝ ⎠⎢ ⎥⎣ ⎦

ggGS o fssw sw D o g GD sw

gs o fsGD gg

gg gg

VD VC I g P E = V I R C f 1+ + v (th) I gC V 1- -V v

⎡ ⎤⎢ ⎥⎛ ⎞⎢ ⎥∴ ⎜ ⎟⎢ ⎥⎝ ⎠⎢ ⎥⎣ ⎦

Substituting the values given Psw = 32 mw,

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